An in situ forming hydrogel has emerged as a promising wound dressing recently. As physically crosslinked hydrogels are normally unstable, most in situ forming hydrogels are chemically cross-linked. However, big concerns have remained regarding the slow gelation and the potential toxicity of residual functional groups from cross-linkers or the polymer matrix. Herein, we report a sprayable in situ forming hydrogel composed of poly(Nisopropylacrylamide 166 -co-n-butyl acrylate 9 )-poly(ethylene glycol)-poly(N-isopropylacrylamide 166 -co-n-butyl acrylate 9 ) copolymer (P(NIPAM 166 -co-nBA 9 )-PEG-P(NIPAM 166 -co-nBA 9 ), denoted as PEP) and silver-nanoparticles-decorated reduced graphene oxide nanosheets (Ag@rGO, denoted as AG) in response to skin temperature. This thermoresponsive hydrogel exhibits intriguing sol−gel irreversibility at low temperatures for the stable dressing of a wound, which is attributed to the inorganic/polymeric dual network and abundant coordination interactions between Ag@rGO nanosheets and PNIPAM. The biocompatibility and antibacterial ability against methicillin-resistant Staphylococcus aureus (MRSA) of this PEP-AG hydrogel wound dressing are confirmed in vitro and in vivo, which could transparently promote the healing of a MRSA-infected skin defect.
Antibacterial efficiency can be effectively improved by applying targeting antibacterial materials and strategies. Herein, the successful synthesis of uniform pH-responsive Ag nanoparticle clusters (AgNCs) is demonstrated, which can collapse and reassemble into nonuniform Ag NPs upon exposure to the acidic microenvironment of bacterial infections. This pH triggered reassembly contributes greatly to the improved antibacterial activities of AgNCs against both methicillin-resistant Staphylococcus aureus (MRSA) and Escherichia coli (E. coli). The minimum inhibitory concentration and minimum bactericidal concentration against MRSA are as low as 4 and 32 µg mL −1 (which are 8 and 32 µg mL −1 for E. coli), respectively. In vivo skin wound healing experiments confirm AgNCs can serve as an effective wound dressing to accelerate the healing of MRSA infection. The development of responsive AgNCs offers new materials and strategies in targeting antibacterial applications.
The abuse of antibiotics resulted in the emergence of antibiotics-resistant
bacteria, which has raised a great social concern together with the
impetus to develop effective antibacterial materials. Herein, the
synthesis of biocompatible enzyme-responsive Ag nanoparticle assemblies
(ANAs) and their application in the high-efficiency targeted antimicrobial
treatment of methicillin-resistant Staphylococcus aureus (MRSA) have been demonstrated. The ANAs could collapse
and undergo stable/collapsed transition on approaching MRSA because of the serine protease-like B enzyme proteins (SplB)-triggered
decomposition of the branched copolymers which have been employed
as the macrotemplate in the synthesis of responsive ANAs. This transition
contributed greatly to the high targeting affinity and efficiency
of ANAs to MRSA. The minimum inhibitory concentration
and minimum bactericidal concentration against MRSA were 2.0 and 32.0 μg mL–1, respectively.
Skin wound healing experiments confirmed that the responsive ANAs
could serve as an effective wound dressing to accelerate the healing
of MRSA infection.
Current surgical single modality treatments for hepatocellular carcinoma (HCC) were restricted by recurrence, blood loss, significant trauma, and poor prognostic. Although multidisciplinary strategies for HCC treatment have been highly recommended by the clinical guidelines, there was limited choice of materials and treatments. Herein, we reported an in situ formed magnetic hydrogel with promising bioapplicable thermal-responsiveness, strong adhesion in wet conditions, high magnetic hyperthermia, and biocompatibility, leading to efficient HCC multidisciplinary treatment including postoperative treatment and transarterial embolization therapy. In vivo results indicated that this hydrogel could reduce the postoperative recurrence rate. The hemostatic ability of the thermal-responsive hydrogel was further demonstrated in both the liver scratch model and liver tumor resection. Computed tomography imaging suggested that the hydrogel could completely embolize the arterial vessels of rabbit liver tumor by vascular intervention operation, which could serve as multidisciplinary responsive materials to external magnetic field and body temperature for HCC treatment.
Activatable cell-penetrating peptide (ACPP) conjugated polymeric nanoparticles containing gadolinium (Gd)chelates and aggregation-induced emission fluorogens (AIEgens) have been synthesized and applied as a magnetic resonance imaging (MRI) and fluorescence imaging (FI) bimodal imaging probe with active tumor targeting. The polymeric nanoparticles have been generated by dissolving presynthesized linear block copolymers into water directly. With AIEgens, N-BP5-Gd-ACPPs showed tumor cell penetration, which can be characterized by in vitro FI. Preliminary in vivo experiments of Gd-chelated nanoparticles have demonstrated promising characteristics as a tumor-targeting MRI contrast agent with good biocompatibility. This study impacts the synthesis of functional copolymers and polymeric nanoparticles for their applications in bioimaging.
In article number 2000511, Zhengbao Zha, Tao He, and co‐workers design uniform pH‐responsive Ag nanoparticle clusters, triggered by the acidic micro‐environment of bacterial infections, that could collapse and re‐assemble into nonuniform Ag NPs assemblies, which result in improved antibacterial activities against methicillin‐resistant Staphylococcus aureus and Escherichia coli.
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